Communication devices, systems, software and methods employing symbol waveform hopping

ABSTRACT

Systems, devices, and methods of the present invention facilitate secure communication by altering the set of symbol waveforms that may be in use in particular symbol times defined herein as Symbol Waveform Hopping. SWH may be enabled by selecting two or more modulation formats that have sufficiently comparable communication performance (e.g., occupied bandwidth and signal power efficiency), but characterized by symbol waveform alphabet that include different symbol waveform, so that the overall transmission/communication performance of data stream in a signal transmission channel of the system is not significantly affected by switching between modulation formats. Some or all of the symbol waveforms in each alphabet may not be present in other alphabets.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 16/819,125 filed Mar. 15, 2020, which claims the benefit of and priority to and from U.S. Provisional Patent Application No. 62/848,279, filed on May 15, 2019, entitled “Communication Devices, Systems, Software and Methods employing Symbol Waveform Hopping”, the entire contents of each application is hereby incorporated by reference.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was made with government support under Award #1738453 awarded by the National Science Foundation. The government has certain rights in the invention.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates in general to data transmission, and more particularly relates to transmitting data in a single data stream using multiple modulation formats to make the data more difficult for unintended recipients to receive.

Background Art

For many purposes, there is a need to secure communications from interception, or in some cases even from detection. This problem is described as “low probability of intercept/low probability of detection” (LPI/LPD).

A first level of security is generally associated with encrypting the data, transmitting and receiving the encrypted data, and decrypting the data. Another level of security may be to vary the transmission channel over which the data is sent. For example, frequency-hopping spread spectrum (FHSS) may be employed. FHSS sends data using multiple carrier frequencies and switches between the multiple carrier frequencies using a pseudorandom sequence known to the transmitter and receiver. FHSS is also the basis for Code-Division Multiple Access (CDMA).

With the continuing increase in signal processing capabilities available to adversaries, it is a continuing challenge to securely encrypt and transmit with LPI/LPD. As such, there is a continuing need for system, devices, software, and methods that may be used to make it more difficult for adversaries to intercept and access the data being transmitted through communication systems.

BRIEF SUMMARY OF THE INVENTION

Systems, devices, software, and methods of the present invention enable the enhancement of LPI/LPD communication by switching between symbol waveforms used to transmit data in a data stream. Varying symbol waveforms carrying the data stream in a transmitted signal during transmission presents a potential adversary with the problem of not knowing the modulation format of the transmitted signal, as the symbol waveforms to be recognized may change randomly and as often as every symbol time in the data stream being transmitted via the transmitted signal.

Unlike the prior art modulation formats, which are predominantly based on constant amplitude sinusoids over each symbol time, the present invention enables the use of more general symbol waveforms, such as polynomial symbol waveforms (PSWs), that allow for the creation of very different modulation formats with comparable transmission/communication performance, thereby enabling symbol waveform variation in a single data stream during transmission of the signal without a loss of performance in the transmitted signal. The variation of symbol waveforms used in the transmission of a bit stream in a transmission signal is referred to herein as “Symbol Waveform Hopping” (SWH). SWH may employ multiple symbol waveform alphabets, each alphabet including multiple symbol waveforms that may be different between the alphabets and switch between the different symbol waveform alphabets during the transmission signal at various transmission times according to a sequence, e.g., pseudo-randomly, which is predetermined and known to the transmitter and receiver.

SWH may be enabled by selecting two or more modulation formats that have sufficiently comparable transmission/communication performance (e.g., occupied bandwidth and signal power efficiency) so that the overall communication performance of the transmission signal in the system is not significantly affected by switching between modulation formats as indicated by SWH. Also, these two or more modulation formats should be sufficiently distinct that a receiver configured to detect one of these modulation formats will be poorly suited to or unable to recognize the others. Similarly, the first and second formats should be selected so that signals in each format cannot be received and the original bit stream sufficiently reconstituted by a third format. The modulation formats are characterized by symbol waveform alphabets including a set of different symbol waveforms that characterize the modulation format. Some or all of the symbol waveform in each alphabet may not be present in other alphabets.

In various embodiments, a user and/or an automated process may provide to a transmitter and a receiver in a communication system used to transmit data in one data stream or transmission channel a predetermined symbol waveform alphabet sequence and a plurality of symbol waveform alphabets to be used to transmit data via symbol waveforms from the transmitter to the receiver via the one data stream or channel. At least two of the symbol waveform alphabets may include one or more different symbol waveforms as noted above. For any given application of the system, the alphabets may be chosen such that data sent via the symbol waveforms in each alphabet via the one data stream can not be meaningfully detected or received using one of the other alphabets and that each alphabet has a sufficiently similar transmission/communication performance for the specific application and not, necessarily in general.

Data being transmitted through the system in a data stream is converted into a sequence of symbol waveforms that are selected from the plurality of symbol waveform alphabets based on the predetermined symbol waveform alphabet sequence, and then transmitted. The sequence of symbol waveforms may be received by the receiver and converted back into the data based on the predetermined symbol waveform alphabet sequence. In various embodiments, a time-amplitude sequence corresponding to the data may be transmitted by sampling the sequence of symbol waveforms.

The plurality of symbol waveform alphabets used in the methods, systems, and apparatuses may be selected to have similar transmission/communication performance, such as similar OBW and bit error rate (BER) versus additive white Gaussian noise (AWGN) performance. In various embodiments, the plurality of symbol waveform alphabets may be selected to have a number of symbol waveforms equal to a power of two and/or the same number of symbol waveforms. Also, the symbol waveforms may be sized to correspond to one symbol time or other data measure.

In various embodiments, the symbol waveform alphabets may be implemented as one or more lookup tables stored in computer readable medium, memory, or other storage that may be accessed, retrieved, and be otherwise made available for use by the system. The symbol waveform alphabets may be generated as a set of polynomial symbol waveforms and/or as symbol waveforms representative of traditional modulation formats.

In various embodiments, a set of symbol waveform alphabets to transmit data are identified, in which each alphabet includes at least one symbol waveform and has similar overall signal transmission characteristics, but different sets of symbol waveforms from other alphabets. Unique identifiers are assigned to each symbol waveform alphabet and a unique bit string is associated with each symbol waveform in each alphabet.

In preparation for transmission, a data stream is converted into a sequence of bit strings and may be further converted to bit string subsequences. The transmitter and/or other processor upstream from the transmitter may access the symbol waveform alphabet according to the predetermined symbol waveform alphabet sequence and select the symbol waveforms within the accessed symbol waveform alphabet corresponding to the bit string subsequences and provide the sequence of symbol waveforms for transmission.

The predetermined symbol waveform alphabet sequence for a data stream or transmission channel may be provided by the transmitter to the receiver or by the receiver to the transmitter. Alternatively, or in addition, a management system may provide the predetermined symbol waveform alphabet sequence for the data stream to one or both the transmitter and receiver. It will be appreciated that varying the source of the predetermined symbol waveform alphabet sequence may make interception more difficult.

In various embodiments, the predetermined symbol waveform alphabet sequence may not be transmitted, but may be generated at the transmitter and/or receiver based on an initiator code provide by the transmitter, receiver, or management system that results in the sequence being generated by a sequence generator in the transmitter and receiver. The local generation of the predetermined symbol waveform alphabet sequence may increase the security of data passing through the system.

The present invention may be employed alone or in parallel with other encryption techniques known to the art, including FHSS and bit stream/data encryption. In addition, the present invention may be used with single and/or parallel, i.e., multi-channel, transmission techniques, such as MIMO-based systems, etc. For example, one or more of the data streams in a MIMO system may employ the present invention. In addition, the transmit and receive antennas that are using the present invention at any point in time may be changed. Similarly, the present invention may be employed in some or all of the transmitters and receiver pairs in systems, in which each transmitter communicates with each receiver via one data stream or transmission channel.

As may be disclosed, taught, and/or suggested herein to the skilled artisan, the present invention addresses the continuing need for hardware and/or software systems, devices, and methods that secure communications and provide LPI/LPD enhancements.

BRIEF DESCRIPTION OF THE DRAWINGS

Advantages of embodiments of the present invention will be apparent from the following detailed description of the exemplary embodiments thereof, which description should be considered in conjunction with the accompanying drawings, which are included for the purpose of exemplary illustration of various aspects of the present invention to aid in description, and not for purposes of limiting the invention.

FIG. 1 illustrates exemplary data transmission systems.

FIG. 2 illustrates exemplary data transmission systems.

FIG. 3 illustrates an exemplary polynomial symbol waveform alphabet corresponding to the symbol waveforms used by standard 8-PSK with Root Raised Cosine (RRC) filtering, referred to herein as Poly_8PSK.

FIG. 4 is an exemplary BER v AWGN plot for the Poly_8PSK alphabet.

FIG. 5 illustrates an exemplary first polynomial symbol waveform alphabet, referred to herein as MC_OBW_Opt_A.

FIG. 6 is an exemplary BER v AWGN plot for the MC_OBW_Opt_A alphabet.

FIG. 7 illustrates an exemplary polynomial symbol waveform alphabet, referred to herein as MC_OBW_Opt_B.

FIG. 8 is an exemplary BER v AWGN plot for the MC_OBW_Opt_B alphabet.

FIG. 9 depicts an exemplary SWH embodiment in a transmit side of wireless radio system.

In the drawings and detailed description, the same or similar reference numbers may identify the same or similar elements. It will be appreciated that the implementations, features, etc., described with respect to embodiments in specific figures may be implemented with respect to other embodiments in other figures, unless expressly stated, or otherwise not possible.

DETAILED DESCRIPTION OF THE INVENTION

Aspects of the invention are disclosed in the specification and related drawings, which may be directed to specific embodiments of the invention. Alternate embodiments may be devised without departing from the spirit or the scope of the invention. Additionally, well-known elements of exemplary embodiments of the invention will not be described in detail or will be omitted so as not to obscure the relevant details of the invention. Further, to facilitate an understanding of the description, a discussion of several terms used herein may be included.

The word “exemplary” is used herein to mean “serving as an example, instance, or illustration” and not as a limitation. Any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. Likewise, the term “embodiments of the invention” does not require that all embodiments of the invention include the discussed feature, advantage or mode of operation.

Further, many embodiments are described in terms of sequences of actions to be performed by, for example, elements of a computing device. It will be recognized that various actions described herein can be performed by specific circuits (e.g., application specific integrated circuits (ASICs)), by field programmable gate arrays, by program instructions being executed by one or more processors, or by a combination thereof. Additionally, sequence(s) of actions described herein can be considered to be embodied entirely within any form of computer readable storage medium having stored therein a corresponding set of computer instructions that upon execution would cause an associated processor to perform the functionality described herein. Thus, the various aspects of the invention may be embodied in a number of different forms, all of which have been contemplated to be within the scope of the claimed subject matter. In addition, for each of the embodiments described herein, the corresponding form of any such embodiments may be described herein as, for example, “logic configured to” perform the described action. For example, it will be appreciated that transmitters, receivers, management systems, and other devices in systems of the present invention may include one or more processors, memory, storage, input and components, communication interfaces, as well as other components that may be interconnected as desired by the skilled artisan via one or more buses and circuit boards, cards, etc.

Systems, devices, software, and methods of the present invention enable the enhancement of LPI/LPD communication by switching between symbol waveforms used to transmit data over a single data stream or transmission channel. Varying symbol waveforms used in the transmission channel at varying times during transmission presents a potential adversary with the problem of not knowing the format of a transmitted signal, as the symbol waveforms using in the transmitted signal to be recognized may change randomly and as often as every symbol time.

As used herein, unless otherwise stated, a transmission channel generally refers to one data stream being transmitted as one transmitted signal. The data stream itself may be comprised of multiple low data rate streams that have been multiplexed together prior to transmission as a single data stream. Conversely, one higher data rate stream may be demultiplexed in multiple lower data rate streams and transmitted via a corresponding multiple of lower data rate streams and channels.

Unlike the prior art modulation formats, which are based on constant amplitude sinusoids with stationary spectrums that provide very different communication performance, if the waveform design is significantly altered e.g. by altering phase separation, the present invention enables the use of symbol waveforms, such as polynomial symbol waveforms (PSWs), that allow for the creation of different modulation formats with comparable communication performance, thereby enabling symbol waveform variation in a single data stream or transmission channel during transmission without a loss of performance. Modulation formats may be represented as symbol waveform alphabets that include one or more symbol waveforms. The symbol waveforms may be based on constant amplitude sinusoids with stationary spectrums as well as varying amplitude waveforms with non-stationary spectrums to form alphabets including different symbol waveforms, but provide similar transmission/communication performance or sufficient performance such that data may be transmitted via the alphabet and received by a receiver in a specific application in one transmission channel.

The variation of symbol waveforms and specifically waveform alphabets used in the transmission channel during the transmission of a bit stream is referred to herein as “Symbol Waveform Hopping” (SWH). SWH employs multiple symbol waveform alphabets for a signal transmission channel and switches between the different symbol waveform alphabets used to transmit the signal during various transmission times according to a predetermined symbol waveform alphabet sequence, e.g., pseudo-randomly, known to the transmitter and receiver. For example, if two alphabets A and B are used for one data stream, the predetermined sequence may be 3A2B1A3B . . . s selected by a user or generated randomly or otherwise. In addition, the alphabet sequence used in the transmission channel may be varied at random or periodic intervals as may be desired. Predetermined merely means that the sequence is known to the transmitter before transmission and to the receiver before reception sufficiently to enable transmission and successful reception of the data in the transmission channel using the sequence. In various embodiments, the sequence may only be known to the transmitter and receiver transmitting the data and not to the management system or other devices or users, or to some portion of those entities.

SWH may be enabled by selecting two or more modulation formats that have sufficiently comparable communication performance for an application (e.g., occupied bandwidth and signal power efficiency) so that the overall communication performance of a transmission channel of the system is not significantly affected by switching between modulation formats as indicated by SWH. In addition, the two or more modulation formats used for SWH should be sufficiently distinct that a receiver set to detect a transmitted signal in one of these modulation formats will be poorly suited to or unable to recognize transmitted signals in the other formats. For example, two alphabets A and B must be sufficiently distinct, such that when the receiver is set detect alphabet A, it can not detect alphabet B and vice versa. Similarly, the first and second formats should be selected so that transmitted signals in each format cannot be received and the original bit stream sufficiently reconstituted by a third format.

Some or all of the symbol waveforms in each alphabet may not be present in other alphabets. The skilled artisan will appreciate that the differentiation between the symbol waveforms in each alphabet may depend upon various factors, such as the network, application, etc. For example, it may be desirable to include some alphabets with some or many similar waveforms for some applications and no similar waveforms in other applications.

For any given application of the system 10, the alphabets may be chosen such that data sent via the symbol waveforms in each alphabet can not be meaningfully detected or received using one of the other alphabets and that each alphabet has a sufficiently similar transmission/communication performance for the specific application and not, necessarily in general. For example, if alphabet A and B can be reliably transmitted 1000 km and 2000 km, respectively, in a transmission channel of a system, then the performance of these alphabets may be similar and data can be reliably transmitted and received using both alphabets for transmission distance less than 1000 km and not for distance greater than 1000 km. It will be appreciated that it may be possible to detect transmitted signals sent with the various alphabets and convert the signal into bits, but the selection of the alphabets is such that the data can not be received, i.e., recovered from the transmitted signal and bits in useful manner, using the other alphabets.

The difference between the symbol waveforms in each alphabet can range from one to all, as the variations in the symbol waveforms merely needs to be sufficient that a data stream sent via each alphabet can not be determined by detecting the other alphabets. In various embodiments, it may be possible to have two or more alphabets, e.g. A and B, of a larger set of alphabets, A-C, where data sent via A or B could be determined by A or B, so long as alphabet C could not determine the data sent using A or B and data sent using C could not be determined using A or B.

Spiral and polynomial based modulation techniques may be useful for generating symbol waveforms in the present invention. These techniques may be used to produce formats with non-stationary spectra, which provides additional freedom in generating symbol waveforms that provide comparable communication performance. For additional information on spiral and polynomial waveform design and modulation, see, for example, U.S. Pat. No. 8,472,534 entitled “Telecommunication Signaling Using Non-Linear Functions”, U.S. Pat. No. 8,861,327 entitled “Methods and Systems for Communicating”, U.S. Pat. No. 10,069,664 entitled “Spiral Polynomial Division Multiplexing” (SPDM), and U.S. patent application Ser. No. 16/735,655 filed Mar. 6, 2020 entitled “Devices, Systems, And Methods Employing Polynomial Symbol Waveforms”, the contents of which are herein incorporated by reference in their entirety, except for the claims and any disclosure contrary to this disclosure, and Prothero, J., Islam, K. Z., Rodrigues, H., Mendes, L., Gutiérrez, J., & Montalban, J. (2019), Instantaneous Spectral Analysis. Journal of Communication and Infotmation Systems, 34(1), 12-26, doi.org/10.14209/jcis.2019.2.

FIG. 1 shows exemplary systems 10 including exemplary an transmitter 12 and receiver 14 that may be used to transmit a data stream as one transmission channel in transmission or communication systems, such as further shown in FIG. 2. Bits, usually representing data/information, being transmitted as a data stream through the transmission channel in the system 10 may be converted to symbol waveforms in a channel encoder 16 section of the transmitter 12, as well as have other signal processing, e.g., forward error correction, performed to prepare the transmission signal.

The symbol waveforms may then be used to modulate a carrier provided by a carrier source 20 using an external modulator 22 as shown in FIG. 1 or to directly modulate the carrier source 20 to produce the transmission signal that may be transmitted via an antenna in a wireless system or an electrical wire or optical fiber in a wired system. The symbol waveforms may be transmitted using multiple carriers simultaneously, such as when implemented with Instantaneous Spectral Analysis (“ISA”), see U.S. Pat. No. 10,069,664 incorporated above, which may be implemented using MIMO, subcarriers, other multiple channel/data stream configurations or via separate single channel transmitter and receiver pairs. For example, the same or different alphabet sequences and/or alphabets may be used in multiple channel transmission, such as MIMO systems.

FIG. 2 may include multiple channel embodiments that may employ MIMO, inverse multiplexing, etc., and the present invention may be employed on one or all of the data streams depending upon the level of protection desired by the user of the system 10. In FIG. 2, one or more of the transmitters 12 may be included in a transmit base station, 1-N, with transmit antennas and a receive base station may include a plurality of the receivers 14, 1-M, where N may usually equal M, but does not have to equal it. The use of the present invention on one or more data streams in the multi-data stream system may be used such that only one of the receivers may receive a data stream employing SWH, even though multiple receivers may be collocated. Furthermore, SWH may be employed on some transmission channels and not other channels, but the receiver may be configured via software and/or hardware to only recombine the SWH channels. The non-SWH channels may be used for less sensitive information including telemetry, etc.

The encoder 16 and decoder 18 are shown as single blocks in FIG. 1. However, the encoder 16 and decoder 18 may include one or more stages/components that are used to process the information passing through the system 10. The encoding and decoding function may be performed inside and/or outside the transmitter 12 and receiver 14, as desired by the skilled artisan.

At the receiver 14, the transmitted signal may be provided to a detector 24 via an antenna in a wireless system or an electrical wire or optical fiber in a wired system. The detector 24 may detect the transmission signal directly or indirectly via known methods suitable for the system 10 and provide the transmission signal to signal processors, which may include the decoder 18 to perform any decoding necessary to convert the signal from the SWH format and output the bits. The bits output from the system 10 may be in the form of data and clock signals, or otherwise.

In various embodiments, the system 10 may be locally and/or remotely monitored and/or controlled by a management system 25 as is known in the art. The system 10 may be deployed as part of a local wired and wireless private point-to-point network, as well as part of the global terrestrial and satellite wired and wireless infrastructure and managed accordingly.

FIG. 2 shows exemplary systems 10 that include a plurality of transmitters 12 and receivers 14 that may be deployed in various transmission and communication systems employing various wired and wireless transmission media 26 and may include symbol waveform hopping technology of the present invention. For example, systems 10, such as shown in FIG. 1 and FIG. 2 and other systems, may be deployed in various electrical and optical wired transmission and communication networks, as well as satellite and terrestrial wireless networks. In various systems, the transmission signals may be multiplexed in a multiplexer 28 before transmission and may require demultiplexing before detection in a demultiplexer 30 after transmission, as is commonly performed in wired and wireless systems carrying multiple channels.

In other embodiments, such as MIMO systems, a higher data rate input signal at a transmit base station may be separated and transmitted as multiple lower data rate streams in multiple transmission channels that are received by multiple receivers and recombined to output a single data stream at the receive base station. SWH may be employed on some or all of the multiple lower data rate streams as desired by the user of the system.

The symbol waveform alphabets that may be used in the system 10 may be maintained proximate or in the various transmitters 12, receivers 14, and management system 25, as well as in other locations that may be accessed by user and the management system 25, via an automated process or otherwise, and provided to the transmitters 12 and receivers 14. It will be appreciated that the user may be the owner of the data being transmitted, a system administrator or operator, a trusted third party, etc. as decided by the parties involved.

In various embodiments, the symbol alphabets that are to be used in the system 10 may be maintained in a computer readable storage medium/memory/storage in the transmitters 12 and receivers 14, such as stored in one or more look-up tables or other formats that may be accessed by processors running on the devices. The alphabets and the alphabet sequence may be locally and/remotely installed or provided to the equipment at various points in time ranging from the initial deployment of the equipment to just prior to use in transmission.

In various embodiments, the SWH technology of the present invention described herein may be implemented as follows:

-   -   1. Identify a set of symbol waveform alphabets to be used to         transmit bits in the hardware and/or software system. The         alphabets may be designed using techniques disclosed in U.S.         patent application Ser. No. 16/735,655, incorporated above, or         other techniques. The set of symbol waveform alphabets may be         designed to have similar OBW, signal power efficiency, and/or         other characteristics, so that the overall signal transmission         characteristics of a transmitted signal in a transmission         channel are not sufficiently altered by switching between symbol         waveform alphabets to prevent efficient transmission of the         underlying data. Simulation software and/or hardware         transmission tests may be used to compare the performance         characteristics of various symbol waveform alphabets in various         transmission channels and systems. Modulation formats that have         similar OBW and bit error rate (BER) versus additive white         Gaussian noise (AWGN) performance may be suitable candidates for         various SWH applications.     -   The skilled artisan may vary the criteria used for selecting         modulation formats depending upon the specific application. For         example, in various embodiments, the number of symbol waveforms         in each alphabet may be selected to be a power of two or not.         Similarly, the symbol waveform alphabets may or may not include         the same number of symbol waveforms.     -   2. Assign a unique identifier to each symbol waveform alphabet.     -   3. Associate a unique bit string to each symbol waveform in each         alphabet.     -   4. Prior to communicating a message, i.e., information/data, via         a transmission channel, establish a symbol waveform alphabet         sequence that is known, or predetermined, to transmitter(s) and         receiver(s) involved in the message communication identifying         the particular symbol waveform alphabet to be used to generate         symbol waveforms at particular times for sending the message.         This sequence may be expressed in terms of the unique symbol         waveform alphabet identifiers or otherwise and be a         pseudo-random sequence or other sequence.     -   5. Convert the message into at least one bit string for         communication.     -   6. Convert the bit string(s) in subsequences of bits. For         example, the length of subsequence may be set to the log base         two of the number of symbol waveforms in each symbol waveform         alphabet in the set of symbol waveform alphabets. Each such bit         string subsequence may be transmitted in one symbol time.     -   7. Retrieve, at the start of each symbol time, by the         transmitter(s) and receiver(s), the symbol waveform alphabet         according to the predetermined symbol waveform alphabet sequence         provided to the transmitter(s) and receiver(s). In an exemplary         implementation, the symbol waveform alphabets may be stored in         lookup tables or other formats in hardware, e.g., computer         readable medium, memory, or other storage, either in or         proximate the transmitters and receivers, transitory and/or         non-transitory form. Each symbol waveform may be represented by         samples taken by evaluating the symbol waveform over the symbol         time duration.     -   8. Select, at the start of each symbol time, the symbol waveform         within the selected symbol waveform alphabet that corresponds to         a bit substring.     -   9. Transmit, by the transmitter, the waveform corresponding to         the selected symbol waveform via the transmission channel. The         symbol waveforms to be transmitted may also be time sampled to         produce a time-amplitude sequence prior to transmission of the         data stream.     -   10. Receive, by the receiver, the transmitted signal. In an         exemplary embodiment, the receiver may use minimum distance         signal detection.     -   11. Convert the received signal into the bit substring based on         the symbol waveform alphabet according the alphabet sequence.     -   12. Reassemble the message from the received and converted bit         substrings.

One of ordinary skill will appreciate that #1-3 of the above procedure may be performed at most times in advance of the actual data transmission via the transmission channel in the system 10 and #4 may be performed up to the time of data transmission as a data stream through the transmission channel. For example, the symbol waveform alphabets may be generated and/or selected by any skilled practitioners associated with any entity involved in the data transmission including the data owner and/or transmission system/network operator, information technology administrator, etc. using one or more of the various techniques described in the reference cited and incorporated herein.

In various embodiments, the predetermined symbol waveform alphabet sequence may or may not be transmitted between the transmitter 12 and receiver 14 and/or from the management system 25. For example, the predetermined symbol waveform alphabet sequence may be generated via processor in or near the transmitter 12 and/or receiver 14 based on an initiator code provided by the transmitter 12, receiver 14, or management system 25 that results in the predetermined symbol waveform alphabet sequence being locally generated and known to each device. The local generation of the predetermined symbol waveform alphabet sequence may increase the security of data passing through the system 10.

In operation, SWH may be applied to new or existing modulation formats. For example, the aforementioned method was applied to generate symbol waveforms for use in combination with, or in lieu of, 8 state phase shift keying (8PSK) format. For purposes of demonstration and comparison, a polynomial symbol waveform (symbol waveform) alphabet was generated that is representative of a standard 8PSK format with Root Raised Cosine (RRC) filtering by starting with 8 sinusoidal polynomials having even phase offsets between them, then convolving with a polynomial corresponding to an RRC with α=0.1, referred to herein as Poly_8PSK.

FIG. 3 illustrates the resulting polynomial symbol waveform alphabet corresponding to Poly_8PSK. As can be seen, the waveforms are symmetric about the x-axis and offset in phase. Transmission of a signal employing the Poly_8PSK alphabet was simulated using MATLAB. The occupied bandwidth (OBW) of the signal was determined using the MATLAB obw function based on a Fourier analysis of the signal to be 2.3 MHz.

For comparison, the OBW of the transmitted signal using Poly_8PSK was also calculated using a software spectrum analyzer (SSA), such as described in U.S. patent application Ser. No. 17/099,643 filed Nov. 16, 2020 entitled Devices, Systems, and Software including Signal Power Measuring and Methods and Software for Measuring Signal Power, which is incorporated by reference in its entirety, except for the claims and any disclosure contrary to this disclosure. The SSA, unlike Fourier analysis, does not require the signal to have a stationary spectrum, which enables the SSA to be applied to a wider range of modulation formats, e.g., polynomial symbol waveform with non-stationary spectrums and constant amplitude sinusoid with stationary spectrum alphabets.

The OBW of the transmitted signal was calculated using the SSA was also found to be 2.3 MHz. The agreement between the Fourier-based OBW calculation and the SSA was expected because the Poly_8PSK alphabet is a stationary spectrum format just like 8PSK and the other constant amplitude sinusoidal-based modulation formats.

FIG. 4 shows exemplary results for bit error rate (BER) versus additive white Gaussian noise (AWGN) calculations for transmitted signals using the Poly_8PSK alphabet. As can be seen, the BER vs. AWGN performance of the transmitted signal agrees well with the theoretical BER v AWGN performance for 8PSK.

Given the Poly_8PSK modulation format alphabet as a baseline, the present invention was applied to develop additional symbol waveforms that may be appropriately used to perform the SWH method. A first modulation format was developed using the techniques described in U.S. patent application Ser. No. 16/735,655, incorporated above and optimized using a Monte Carlo method to have an OBW of the received signal similar to Poly_8PSK alphabet, while retaining from prior design BER vs. AWGN performance (signal power efficiency) greater than Poly_8PSK alphabet.

FIG. 5 shows the polynomial symbol waveform alphabet generated as the first modulation format, referred to herein as the MC_OBW_Opt_A alphabet. As can be seen in the figure, while somewhat resembling the Poly_8PSK alphabet (FIG. 3), the MC_OBW_Opt_A alphabet has a different structure in that it includes symbol waveforms with forms, or shapes, that are significantly different than the symbol waveforms in the Poly_8PSK alphabet. In addition, some of waveforms are non-sinusoidal with a non-stationary spectrum. As such, the SSA was used to calculate the OBW for each received signal and various calculations were performed using Monte Carlo techniques to optimize the alphabet for use with SWH.

The calculations were performed according to the following process:

-   -   The simulated symbol time was 1 microsecond in all calculations.     -   All alphabets were of size 8, corresponding to 3 bits per         symbol.     -   Each polynomial symbol waveform was sampled 25 times in every         symbol time.     -   OBW was measured in terms of 99% single-sided power occupancy,         on streams of 15,000 simulated bits transmitted in a single         channel.     -   In all polynomial symbol waveform alphabets studied, all         polynomials were individually power normalized to the same value         of 0.1, in arbitrary units.     -   Signal power efficiency of the received signal was measured in         terms of BER vs. AWGN over a simulated signal length of 1.5         million bits transmitted per AWGN level.     -   For purposes of logarithmic plotting, a bit error rate (BER) of         zero was mapped to 10e-6.     -   All polynomial symbol waveform alphabets were Gray coded to         maximize BER performance in the presence of symbol detection         errors induced by AWGN.

FIG. 6 shows the BER v AWGN results for a single data stream transmitted and received using the MC_OBW_Opt_A symbol waveform alphabet. As can be seen, the performance is approximately 2-3 dB better than Poly_8PSK alphabet. In addition, the OBW performance of MC_OBW_Opt_A alphabet is 2.3 MHz, which is substantially the same as the Poly_8PSK alphabet.

FIG. 7 shows a second modulation format, referred to herein as MC_OBW_Opt_B alphabet, that was generated for use in SWH methods of the present invention. The second modulation format was generated starting from the Poly_8PSK alphabet and then optimizing the design of the alphabet for BER v AWGN performance, while maintaining the OBW of the Poly_8PSK alphabet. As can be seen in FIG. 7, the MC_OBW_Opt_B alphabet, while resembling the Poly_8PSK alphabet (FIG. 3), has a different structure in that it includes symbol waveforms with forms that are significantly different than the symbol waveforms in the Poly_8PSK alphabet and also has some non-sinusoidal waveforms.

FIG. 8 shows the BER v AWGN results for a single data stream transmitted and received using the MC_OBW_Opt_B alphabet. As can be seen, the performance is also approximately 2-3 dB better than Poly_8PSK alphabet. The OBW performance of MC_OBW_Opt_B alphabet remains 2.3 MHz, which is consistent with OBW for Poly_8PSK alphabet.

The similar transmission/communication performance of the MC_OBW_Opt_A and MC_OBW_Opt_B alphabets, while having different waveforms, suggests that various combinations of the two alphabets may be useful for implementing SWH technology in various systems. It will be appreciated that for applications in which Poly_8PSK may provide acceptable communication performance, SWH may be implemented using Poly_8PSK along with MC_OBW_Opt_A and MC_OBW_Opt__B based on the different symbol waveforms in each alphabet. For example, systems that currently employ 8PSK modulation formats may be candidates for SWH technology employing these alphabets.

One of ordinary skill will further appreciate that other alphabets with similar transmission performance characteristics may be used in combination with, or in lieu of, one, some, or all of these alphabets. It will be further appreciated that 8-symbol alphabets have been used herein for exemplary purposes. SWH may be based on other alphabet sizes, e.g., 4, 16, or 64, 128, 512 symbol waveforms, and other modulation formats. In some applications, it may be desirable to employ various combinations of stationary and/or nonstationary waveforms in SWH embodiments, depending upon channel conditions, data throughput requirements, or other considerations.

FIG. 9 shows exemplary embodiments of the transmit side of the wireless radio communication system 10 in which SWH may be employed using 10 different alphabets with each alphabet including 8 unique symbols. There was be a corresponding receive side in the system 10, which is not shown for ease of depiction. In this example, there may be as many as 80 different waveforms to distinguish and analyze merely to receive the signal at the physical layer. One of ordinary skill in the art will appreciate that the wireless communication system embodiments depicted in FIG. 9 may be implemented in various single and multiple cellular, e.g. 3G/4G/5G, etc., satellite and other wireless systems, as well as various channel electrical and optical wired systems as are or may be known in the art.

The foregoing description and accompanying drawings illustrate the principles, preferred embodiments and modes of operation of the invention. However, the invention should not be construed as being limited to the particular embodiments discussed above. Additional variations of the embodiments discussed above will be appreciated by those skilled in the art.

Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive. Accordingly, it should be appreciated that variations to those embodiments can be made by those skilled in the art without departing from the scope of the invention as defined by the following claims. 

What is claimed is:
 1. A method of data transmission, comprising: providing, via at least one of a processor and a user, to a transmitter and a receiver in communication to transmit data via a single data stream, a predetermined symbol waveform alphabet sequence and a plurality of symbol waveform alphabets corresponding to the symbol waveform alphabet sequence to be used to transmit data via symbol waveforms from the transmitter to the receiver, where data transmitted using at least one symbol waveform alphabet can not be received using the other symbol waveform alphabets, and each alphabet having sufficient transmission performance be used to transmit the data from the transmitter to the receiver; generating the data to be transmitted by separating a higher data rate stream into multiple lower data rate streams, less than all of the lower data rate streams including the data, converting the data into a sequence of symbol waveforms, the symbol waveforms selected from the plurality of symbol waveform alphabets including the at least one symbol waveform alphabet can not be received using the other symbol waveform alphabets and at least one of the other symbol waveform alphabets according to the predetermined symbol waveform alphabet sequence; transmitting, by the transmitter, the sequence of symbol waveforms via the single data stream; receiving, by the receiver, the transmitted sequence of symbol waveforms in the signal data stream; and, converting the received sequence of symbol waveforms into the data based on the predetermined symbol waveform alphabet sequence.
 2. The method of claim 1, where the plurality of symbol waveform alphabets are selected to have similar OBW and bit error rate (BER) versus additive white Gaussian noise (AWGN) performance.
 3. The method of claim 1, where the plurality of symbol waveform alphabets are selected to have a number of symbol waveforms equal to a power of two.
 4. The method of claim 1, where the plurality of symbol waveform alphabets are selected to have the same number of symbol waveforms.
 5. The method of claim 1, further comprising: constructing a time-amplitude sequence corresponding to the data by sampling the sequence of symbol waveforms, where the time-amplitude sequence is transmitted and received.
 6. The method of claim 1, where each symbol waveform is transmitted in one symbol time.
 7. The method of claim 1, where the plurality of symbol waveform alphabets is provided as at least one lookup table.
 8. The method of claim 1, where converting the received waveform includes looking up the received waveform in a lookup table for the symbol waveform alphabet.
 9. The method of claim 1, where no two symbol waveform alphabets include all of the same symbol waveforms.
 10. The method of claim 1, where providing the plurality of symbol waveform alphabets comprises: identifying a set of symbol waveform alphabets to transmit data having similar overall signal transmission performance, with no two alphabets including all of the same symbol waveforms; assigning a unique identifier to each symbol waveform alphabet; and associating a unique bit string to each symbol waveform in each alphabet.
 11. The method of claim 1, where transmitting the sequence of symbol waveforms comprises: converting the data into a sequence of bit strings for transmission; converting the bit strings into bit string subsequences; accessing the symbol waveform alphabets according to the predetermined symbol waveform alphabet sequence; and selecting the symbol waveforms within the accessed symbol waveform alphabet that corresponds to the bit string subsequences to provide the sequence of symbol waveforms for transmission.
 12. The method of claim 1, where the predetermined symbol waveform alphabet sequence is provided by at least one of the transmitters providing the predetermined symbol waveform alphabet sequence to the receiver and the receiver providing the predetermined symbol waveform alphabet sequence to the transmitter.
 13. The method of claim 1, where a management system provides the predetermined symbol waveform alphabet sequence to the receiver.
 14. The method of claim 1, where the predetermined symbol waveform alphabet sequence is randomly generated.
 15. The method of claim 1, where the symbol waveforms in at least two symbol waveform alphabets are sufficiently distinct that the receiver configured to detect one of the symbol waveform alphabets cannot reliably receive the data transmitted in the other symbol waveform alphabets.
 16. A system comprising: a transmitter to receive a message, the message generated by separating a higher data rate stream into multiple lower data rate streams, less than all of the lower data rate streams including the message, and transmit the message as a sequence of symbol waveforms in one transmission channel, the symbol waveforms selected from a plurality of symbol waveform alphabets according to a predetermined waveform alphabet sequence, where the message transmitted in at least one symbol waveform alphabet can not be received using the other symbol waveform alphabets, and each alphabet having sufficient transmission performance to transmit the message from the transmitter to a receiver; and the receiver to receive the sequence of symbol waveforms in the transmission channel, and convert the received symbol waveforms into the message based on the predetermined sequence of the plurality of symbol waveform alphabets, and output the message.
 17. The system of claim 16, where the transmitter is one of a plurality of transmitters and the receiver is one of a plurality of receivers.
 18. The system of claim 17, where the system is a MIMO system.
 19. A non-transitory computer readable medium storing instructions for transmitting data, the instructions comprising: one or more instructions which, when executed by one or more processors, cause the one or more processors to: separate a higher data rate stream into multiple lower data rate streams, less than all of the lower data rate streams including the data, convert the data into a sequence of symbol waveforms, the symbol waveforms selected from a plurality of symbol waveform alphabets, where the data transmitted in one transmission channel in at least one symbol waveform alphabet can not be received using the other symbol waveform alphabets, and each alphabet having sufficient transmission performance to transmit the message from a transmitter to a receiver; and transmit, by the transmitter, the sequence of symbol waveforms using the one symbol waveform alphabet can not be received using the other symbol waveform alphabets and at least one of the other symbol waveform alphabets.
 20. The non-transitory computer readable medium of claim 19, where the one or more instructions, when executed by the one or more processors, further cause the one or more processors to: convert the data into a sequence of symbol waveforms in accordance with a predetermined symbol waveform alphabet sequence; and provide the predetermined symbol waveform alphabet sequence to a receiver to receive the sequence of symbol waveforms transmitted by the transmitter. 